Adenoviral vectors for gene transfer

Effects of Cell Cycle Status on the Efficiency of Liposome-mediated Gene Transfection in Mouse Fetal Fibroblasts

Methods for cell cycle synchronization of mouse fetal fibroblast cells (MFFCs) were first selected and optimized. When MFFCs were cooled at 5 C for different periods of time, the highest percentage of cells at the G0/G1 phase (75.4+/-2.9%), with 3.5+/-0.3% of apoptotic cells, was achieved after 5 h of treatment. Extended cooling increased the number of apoptotic cells significantly. When MFFCs were treated with different concentrations of roscovitine (ROS) for different periods of time, the highest percentage of G0/G1 cells (83.5+/-1.8%), with 9.2+/-0.6% apoptotic cells, was obtained after exposure to 10 microM ROS for 24 h. When the cells were cooled at 5 C for 5 h followed by incubation in 10 microM ROS for 12 h, 83.6+/-1.9% were synchronized at the G0/G1 stage, with 3.6% undergoing apoptosis. Cell cycle progression was then observed after release of the MFFCs from different synchronization blocks. The highest percentages of S and G2/M cells (81% and 75%) were achieved at 12 and 20 h, respectively, after release of the MFFCs from the cooling plus ROS treatment, and these percentages were significantly higher than those obtained after release from the cooling or ROS alone blocks. Finally, MFFCs were transfected with pEGFP-N1 plasmid at the peak of the G0/G1, S, and G2/M phases, respectively, after release from the different blocks and both the transient and stable transfection efficiencies were determined. The GFP gene expression was greatly enhanced when transfection was performed at the time when most cells were at the G2/M stage after release from cooling, ROS alone, and cooling plus ROS treatments. Statistical analysis revealed a close correlation between the rate of G2/M cells and the transient and stable GFP gene expression efficiencies. Together, the results indicated that (a) the best protocol for cell cycle synchronization of MFFCs was a 5-h cooling at 5 C followed by incubation in 10 microM ROS for 12 h which produced both a high rate of synchronization in the G0/G1 phase with acceptable apoptosis and a high rate of G2/M cells after release; and (b) that the cell cycle status had marked effects on the efficiency of liposome-mediated transfection in MFFCs, with the highest transfection efficiency obtained in cells at the G2/M stage.

Efficacy of antigen 2/proline-rich antigen cDNA-transfected dendritic cells in immunization of mice against Coccidioides posadasii

Coccidioides posadasii causes coccidioidomycosis, or Valley fever, in the endemic regions of the Southwestern United States. The susceptibility to C. posadasii infection has been attributed to a decreased Th1 cellular response. APCs, especially dendritic cells (DCs), play an important role in the activation of Th1 response. In this study, we investigated the efficacy of a DC-based vaccine against C. posadasii in a mouse model of coccidioidomycosis. We intranasally immunized C57BL6 mice with syngeneic, bone marrow-derived DCs (JAWS II cells) transfected with a cDNA encoding the protective Coccidioides-Ag2/proline-rich Ag. The immunized mice were lethally challenged with C. posadasii through either an i.p. or intranasal route. Upon necropsy after 10 days of infection, fungal burden in lung and spleen of immunized mice was significantly reduced as compared with the control animals. The lung tissue homogenates of immunized animals showed higher levels of IFN-gamma. Histologically, lung tissues of immunized mice were in better condition than the control mice. To further investigate, we studied the biodistribution and trafficking of injected DCs by nuclear imaging techniques. For this purpose, the transfected DCs were radiolabeled with (111)In-oxime. Scintigraphic images showed that most of the label remained in the gastrointestinal tract. A significant amount was also observed in lung, but there were negligible circulating (111)In label in blood. The results suggest that the DCs have a potent immunostimulatory activity, and immunization with DCs transfected with Ag2/proline-rich Ag-cDNA induces protective immunity against C. posadasii in C57BL6 mice.

Catheter-mediated subselective intracoronary gene delivery to the rabbit heart: introduction of a novel method

BACKGROUND

Recent studies suggest that gene therapy using replication-deficient adenoviruses will benefit treatment of cardiovascular diseases including heart failure. A persistent hurdle is the effective and reproducible delivery of a transgene to the myocardium with minimal iatrogenic morbidity. In this study, we sought to design a relatively non-invasive percutaneous gene delivery system that would maximize cardiac transgene expression and minimize mortality after intracoronary adenovirus injection.

METHODS

Adult rabbits received a left circumflex coronary artery (LCx) infusion of 5x10(11) total viral particles of an adenovirus containing the marker transgene beta-galactosidase (Adeno-betaGal) via either a continuous infusion method utilizing an oxygenated, normothermic, physiologic pH Krebs solution driven by a Langendorff apparatus (n=12) or a timed bolus and set concentration at a constant infusion rate to the LCx (n=12). Six rabbits underwent global transgene delivery via an invasive method involving intraventricular delivery and aortic root cross-clamping. The efficacy of transgene expression via these three distinct delivery methods was determined in the left ventricle at 5 days by histological staining and colorimetric quantification assay.

RESULTS

While the open-chest, aortic cross-clamping method provides the highest level of gene expression throughout the heart, the morbidity of this procedure is clinically prohibitive. Percutaneous LCx delivery of Adeno-betaGal using the Langendorff apparatus was associated with the lowest morbidity and mortality while still supporting significant myocardial gene expression.

CONCLUSIONS

Percutaneous delivery of an adenovirus solution using a continuous infusion of oxygenated Krebs solution via a Langendorff apparatus appears to be a gene delivery modality offering the best compromise of gene expression and clinical utility to maximize any potential therapeutic outcome.

Criteria for the design and biological characterization of radiolabeled peptide-based pharmaceuticals

Radiolabeled peptide-based formulations are being evaluated for their application in oncological imaging and therapy using nuclear medicine techniques. A major breakthrough in the field was the discovery and identification of the G-protein coupled receptor superfamily that are overexpressed in a variety of human cancers. These receptors act as targets for endogenous compounds, often of peptidic nature, which can be radiolabeled and, therefore, could potentially be utilized as radiopharmaceuticals. This general strategy has proven successful for application in humans in only a few cases thus far. However, the use of more sophisticated structural methodology to enhance our understanding of the interactions between the receptor and the endogenous peptide or its analogs, and a more efficient preclinical evaluation process, may help to single out the most promising compounds for further development and eventual use in the clinical application of radiopharmaceuticals. This review analyzes current methods of approaching these key points. The rational process for developing peptide-based radiopharmaceuticals is presented, from the structural analysis of the peptide-receptor interaction for the identification and modeling of the peptide analogs to the synthesis, with an appropriate metal carrier, of compounds that mimic endogenous peptides. Finally, the in vitro and in vivo biological testing and evaluation in preclinical animal models is described. To render the entire process successful, expertise in different areas of drug development is indispensable.

A model for intracellular trafficking of adenoviral vectors

Here we develop an integrative computational framework to model biophysical processes involved in viral gene delivery. The model combines reaction-diffusion-advection equations that describe intracellular trafficking with kinetic equations that describe transcription and translation of the exogenous DNA. It relates molecular-level trafficking events to whole-cell distribution of viruses. The approach makes use of the current understanding of cellular processes and data from single-particle single-cell imaging experiments. The model reveals two important parameters that characterize viral transport at the population level, namely, the effective velocity, V(eff), and the effective diffusion coefficient, D(eff). V(eff) measures virus's net movement rate and D(eff) represents the total dispersion rate. We employ the model to study the influence of microtubule-mediated movements on nuclear targeting and gene expression of adenoviruses of type 2 and type 5 in HeLa and A549 cells. Effects of microtubule organization and the presence of microtubule-destabilizing drugs on viral transport were analyzed and quantified. Model predictions agree well with experimental data available in literature. The paper serves as a guide for future theoretical and experimental efforts to understand viral gene delivery.

Porcine adenovirus as a delivery system for swine vaccines and immunotherapeutics

Porcine adenovirus (PAdV) has many qualities which make it an ideal choice for use as a delivery vector in swine. It is a low grade pathogen, present almost world-wide in a number of serotypes varying in their virulence and tissue tropism, which may allow for serotype specific vaccine targeting. PAdV is species specific having only been isolated from swine, reducing the possibility of its spread to other animals or man following administration. When engineered to contain a foreign gene, recombinant PAdV (rPAdV) can be grown to high titres in tissue culture cells making it cheap to produce. Knowledge of the complete nucleotide sequence of the PAdV genome has enabled rationally directed insertions of foreign genes which remain stably inserted in the genome and can be expressed at high levels following delivery to the target host. Importantly, recombinant PAdV can be administered by injection or by the oral route in feed or drinking water. We have delivered a range of antigens and immunomodulatory molecules to commercially available pigs using rPAdV and found it to be a very effective delivery system. Significantly, recombinant PAdV serotype 3 is highly effective as a delivery vehicle even when administered in the face of high levels of artificially induced serotype specific neutralising antibody to the vector.

Positron emission tomography imaging of adenoviral-mediated transgene expression in liver cancer patients

BACKGROUND & AIMS

In gene-therapy protocols, imaging of gene expression is needed to evaluate the transduction efficiency of the vector, its tissue distribution, and the duration of transgene expression and to assess the feasibility of repeated vector administration.

METHODS

We have used positron emission tomography with a fluorine-18-labeled penciclovir analogue to monitor thymidine kinase gene expression after intratumoral injection of a first-generation recombinant adenovirus in patients with hepatocellular carcinoma. Patients were enrolled in a pilot clinical trial and treated with escalating doses of the vector. Two days after adenovirus inoculation, transgene expression was evaluated during the first hours after administration of the radiotracer both on the treated lesion and on a whole-body basis.

RESULTS

Transgene expression in the tumor was dependent on the injected dose of the adenovirus and was detectable in all patients who received > or = 10(12) viral particles. However, when the study was repeated 9 days after vector injection, no expression could be observed. It is interesting to note that no specific expression of the transgene could be detected in distant organs or in the surrounding cirrhotic tissue in any of the cases studied.

CONCLUSIONS

Our findings show the real possibility of imaging transgene expression in humans by using viral vectors. We show that hepatocarcinoma is a permissive tumor for adenoviral infection and that the nontumoral cirrhotic liver is spared from transduction when the vector is administered by intratumoral injection. These results show that positron emission tomography imaging may help in the design of gene-therapy strategies and in the clinical assessment of new-generation vectors.

Progress towards gene therapy for cystic fibrosis

A decade ago it was widely anticipated that cystic fibrosis would be one of the first diseases to be treated by gene therapy. The difficult hurdle of cloning the responsible gene had been accomplished, its function was established and the lung appeared readily accessible for gene replacement. Since the first clinical trials for cystic fibrosis lung disease in the early 1990s it has become increasingly apparent that successful lung-directed gene therapy is significantly more complex than was first envisioned. Numerous obstacles including vector toxicity, inefficient transgene expression and limited vector production have delayed progress. An increased understanding of vector biology and host interaction has led to the development of novel strategies to enhance the efficiency and selectivity of gene delivery to the lung. Although significant challenges remain, there is now a realistic prospect of a clinically effective treatment in the next 10 years.

Gene therapy for proliferative ocular diseases

Proliferative ocular diseases encompass a wide variety of pathological processes with adverse cellular differentiation, proliferation and migration as common features. Pathologies may involve neovascular responses associated with diabetic retinopathy, retinopathy of prematurity or age-related macular degeneration. These diseases are quite prevalent and account for substantial visual impairment and blindness worldwide. Although treatment strategies are largely surgical, advances in our understanding of the proteins crucial to cell transdifferentiation, proliferation and migration, along with better gene transfer techniques, have greatly increased the potential for biological treatment options. In this report, the most common proliferative ocular vascular diseases and existing therapeutic modalities will be reviewed and an overview of possible gene therapy options will be discussed, along with potential candidate genes.

Targeted modification of atrial electrophysiology by homogeneous transmural atrial gene transfer

BACKGROUND

Safe and effective myocardial gene transfer remains elusive. Heterogeneous ventricular gene delivery has been achieved in small mammals but generally with methods not readily transferable to the clinic. Atrium-specific gene transfer has not yet been reported. We hypothesized that homogeneous atrial gene transfer could be achieved by direct application of adenoviral vectors to the epicardial surface, use of poloxamer gel to increase virus contact time, and mild trypsinization to increase virus penetration.

METHODS AND RESULTS

We "painted" recombinant adenovirus encoding the reporter gene Escherichia coli beta-galactosidase directly onto porcine atria. Investigational variables included poloxamer use, trypsin concentration, and safety. Using the painting method, we modified the atrial phenotype with an adenovirus expressing HERG-G628S, a long-QT-syndrome mutant. Our results showed that application of virus with poloxamer alone resulted in diffuse epicardial gene transfer with negligible penetration into the myocardium. Dilute trypsin concentrations allowed complete transmural gene transfer. After trypsin exposure, echocardiographic left atrial diameter did not change. Left atrial function decreased on postoperative day 3 but returned to baseline by day 7. Tissue tensile strength was affected only in the 1% trypsin group. HERG-G628S gene transfer prolonged atrial action potential duration and refractory period without affecting ventricular electrophysiology.

CONCLUSIONS

We show complete transmural atrial gene transfer by this novel painting method. Adaptation of the method could allow application to other tissue targets. Use with functional proteins in the atria could cure or even prevent diseases such as atrial fibrillation or sinus node dysfunction.

High-level expression of the coxsackievirus and adenovirus receptor messenger RNA in osteosarcoma, Ewing's sarcoma, and benign neurogenic tumors among musculoskeletal tumors

PURPOSE

The sensitivity of human tumor tissues to infection with recombinant adenoviruses correlates with the expression of the coxsackievirus and adenovirus receptor (CAR). CAR has been shown to function as the primary receptor for adenoviruses and to play a critical role in adenovirus entry into host cells. It is important for clinical gene therapy to determine the expression level of CAR in tumor tissues.

EXPERIMENTAL DESIGN

We analyzed the expression of CAR mRNA in 154 musculoskeletal tumor tissues from 154 patients and 10 normal mesenchymal tissues from 3 patients using reverse transcription-PCR and real-time quantitative PCR. An adenovirus infection assay was performed in two cell lines that were established from CAR-positive osteosarcoma tissue and CAR-negative malignant fibrous histiocytoma tissue.

RESULTS

Ninety-nine of 154 tumors were detected as CAR positive by reverse transcription-PCR. We found that the expression levels of CAR mRNA varied markedly between different tumors as determined by real-time quantitative PCR. CAR mRNA was expressed at high levels in osteosarcoma, Ewing's sarcoma, neurofibroma, and schwannoma; at intermediate levels in exostosis, giant cell tumor, liposarcoma, synovial sarcoma, malignant peripheral nerve sheath tumor, and hemangioma; and at low levels in alveolar soft part sarcoma and desmoid. Whereas the osteosarcoma cell line that expressed a high level of CAR mRNA, like its parent tumor, had a high efficiency of adenovirus infection, the malignant fibrous histiocytoma cell line with almost undetectable expression of CAR mRNA, like its parent tumor, had a low efficiency of infection.

CONCLUSIONS

Our data showed the great variations in CAR mRNA expression among human musculoskeletal tumors and mesenchymal tissues and implicated the potential usefulness of adenoviral vectors in gene therapy for osteosarcoma, Ewing's sarcoma, neurofibroma, and schwannoma. Efficient transduction with adenovirus for gene therapy could be realized in appropriate, sensitive tumor types.

Inhibitory G protein overexpression provides physiologically relevant heart rate control in persistent atrial fibrillation

BACKGROUND

The need for new treatment strategies for cardiac arrhythmias has motivated our continuing development of gene therapeutic options. Previously, we reported a decreased heart rate in an acute model of atrial fibrillation after atrioventricular nodal gene transfer. Here, we expand those observations to persistent atrial fibrillation and severe heart failure.

METHODS AND RESULTS

After 3 weeks of atrial fibrillation, domestic swine received atrioventricular nodal gene transfer with adenoviruses encoding beta-galactosidase (beta-gal), wild-type Galpha(i2) (wtGi), or constitutively active mutant (cGi). Heart rates in awake, alert animals were not altered by beta-gal or wtGi. cGi caused a sustained 15% to 25% decrease in heart rate. The wtGi effect became evident with sedation. A tachycardia-induced cardiomyopathy was present before gene transfer. In the beta-gal group, cardiomyopathy worsened over time. In the wtGi group, the condition improved slightly, and in the cGi group, ejection fraction was near normal at the end of the study. TUNEL staining results corroborated this finding.

CONCLUSIONS

cGi overexpression in the porcine atrioventricular node causes physiologically relevant heart rate control in persistent atrial fibrillation. These data advance the development of gene therapy as a potential treatment for common cardiac arrhythmias.

Gene therapy in heart and lung disease

PURPOSE OF REVIEW

Gene therapy utilizes viral and non-viral vectors to transfer genetic material into a host in the hope of treating disease. This article will review the potential applications of gene therapy in the treatment of cardiac and pulmonary diseases.

RECENT FINDINGS

The results from several phase I and II clinical trials have recently been published. In patients with ischemic heart disease, evidence of coronary revascularization has been observed after the delivery of angiogenic factors. Several trials have demonstrated a reduction in anginal symptoms, increases in exercise tolerance, and objective improvements in myocardial perfusion. Evidence of the transfer of therapeutic genes has been observed in human trials of inherited pulmonary diseases. Unfortunately, there has been little evidence of clinical efficacy in these studies. A variety of gene therapy strategies are being explored in the treatment of thoracic malignancies. Partial antitumor responses have occurred in some of the subjects enrolled in these studies.

SUMMARY

Significant progress has been made in the field of gene therapy in the past decade. Data from these early animal and human clinical trials will provide important information to guide future studies.

Gene Transfer for Therapeutic Vascular Growth in Myocardial and Peripheral Ischemia

Therapeutic vascular growth in the treatment of peripheral and myocardial ischemia has not yet fulfilled its expectations in clinical trials. Randomized, double-blinded placebo-controlled trials have predominantly shown the safety and feasibility but not the clear-cut clinically relevant efficacy of angiogenic gene or recombinant growth factor therapy. It is likely that growth factor levels achieved with single injections of recombinant protein or naked plasmid DNA are too low to induce any relevant angiogenic effects. Also, the route of administration of gene transfer vectors has not been optimal in many cases leading to low gene-transfer efficacy. Animal experiments using intramuscular or intramyocardial injections of adenovirus encoding vascular endothelial growth factor (VEGF, VEGF-A), the mature form of VEGF-D, and fibroblast growth factors (FGF-1, -2, and -4) have shown high angiogenic efficacy. Adenoviral overexpression of VEGF receptor-2 ligands, VEGF-A and the mature form of VEGF-D, enlarge the preexisting capillaries in skeletal muscle and myocardium via nitric oxide(NO)-mediated mechanisms and via proliferation of both endothelial cells and pericytes, resulting in markedly increased tissue perfusion. VEGF also enhances collateral growth, which is probably secondary to increased peripheral capillary blood flow and shear stress. As a side effect of VEGF overexpression and rapid microvessel enlargement, vascular permeability increases and may result in substantial tissue edema and pericardial effusion in the heart. Because of the transient adenoviral gene expression, the majority of angiogenic effects and side effects return to baseline by 2 weeks after the gene transfer. In contrast, VEGF overexpression lasting over 4 weeks has been shown to induce the growth of a persistent vascular network in preclinical models. To improve efficacy, the choice of the vascular growth factor, gene transfer vector, and route of administration should be optimized in future clinical trials. This review is focused on these issues.

Rational design and engineering of delivery systems for therapeutics: biomedical exercises in colloid and surface science

Engineering delivery systems of therapeutic agents has grown into an independent field, transcending the scope of traditional disciplines and capturing the interest of both academic and industrial research. At the same time, the acceleration in the discovery of new therapeutic moieties (chemical, biological, genetic and radiological) has led to an increasing demand for delivery systems capable of protecting, transporting, and selectively depositing those therapeutic agents to desired sites. The vast majority of delivery systems physically reside in the colloidal domain, while their surface properties and interfacial interactions with the biological milieu critically determine the pharmacological profiles of the delivered therapeutic agents. Interestingly though, the colloidal and surface properties of delivery systems are commonly overlooked in view of the predominant attention placed on the therapeutic effectiveness achieved. Moreover, the development and evaluation of novel delivery systems towards clinical use is often progressed by serendipity rather than a systematic design process, often leading to failure. The present article will attempt to illustrate the colloid and interfacial perspective of a delivery event, as well as exemplify the vast opportunities offered by treating, analysing and manipulating delivery systems as colloidal systems. Exploring and defining the colloid and surface nature of the interactions taking place between the biological moieties in the body and an administered delivery vehicle will allow for the rational engineering of effective delivery systems. A design scheme is also proposed on the way in which the engineering of advanced delivery systems should be practiced towards their transformation from laboratory inventions to clinically viable therapeutics. Lastly, three case studies are presented, demonstrating how rational manipulation of the colloidal and surface properties of delivery systems can lead to newly engineered systems relevant to chemotherapy, gene therapy and radiotherapy.

A genetically retargeted adenoviral vector enhances viral transduction in esophageal carcinoma cell lines and primary cultured esophageal resection specimens

OBJECTIVE

To evaluate if an integrin-retargeted adenoviral vector could establish a more efficient and tumor-specific gene transfer in esophageal carcinoma cells.

SUMMARY BACKGROUND DATA

Although preclinical data indicated that adenoviral gene therapy could be a promising novel treatment modality for various malignancies, clinical results are often disappointing. An important problem is the decreased tumoral expression of the Coxsackie and adenovirus receptor (CAR), which mediates adenoviral entry. Retargeting the adenoviral vector to other cellular receptors, by inserting an arginine-glycine-aspartate (RGD) tripeptide in the fiber knob, might overcome this problem.

METHODS

Four esophageal carcinoma cell lines and 10 fresh surgical resection specimens were cultured. All were infected with the native adenovirus (Ad) and the retargeted adenovirus (AdRGD), encoding for the reporter genes luciferase or Green Fluorescent Protein to analyze gene transfer efficiency.

RESULTS

In all cell lines, an increase in viral expression per cell and an increase in the percentage of transduced cells were seen with the retargeted adenovirus. Also, in the primary cultures of carcinoma cells, a more efficient gene transfer was seen when the retargeted vector was used. This phenomenon was less pronounced in normal cells, indicating that the RGD virus transduces tumor cells more efficiently than normal cells.

CONCLUSIONS

This study demonstrates that an RGD retargeted adenovirus infects human esophageal carcinoma cells with enhanced efficiency, while in normal esophageal cells this effect is less pronounced. Therefore, this retargeted vector is expected to have a better performance in vivo, when compared with nonretargeted vectors used for cancer gene therapy so far.

Robust adenoviral and adeno-associated viral gene transfer to the in vivo murine heart: application to study of phospholamban physiology

BACKGROUND

Viral gene transfer to the whole heart in vivo has been achieved in several mammalian species but remained difficult to accomplish in murine hearts. We postulated that a key impediment derives from the use of proximal aortic occlusion during virus injection, because this eliminates coronary perfusion gradients in mice as aortic root and left ventricle pressures equalize.

METHODS AND RESULTS

Pressure-volume analysis confirmed these mechanics. In contrast, descending aortic occlusion with whole-body cooling (20 degrees C) preserved transmyocardial perfusion gradients and allowed for sustained (>10-minute) dwell times in an upper-body perfusion circuit. This approach yielded robust cardiac transfection with adenovirus (AdV) and adeno-associated virus (AAV) injected into the left ventricle cavity or more simply via a central vein. Cardio-specific expression was achieved with a myocyte-specific promotor. Optimal AdV transfection required 9-minute aortic occlusion, versus 5-minute occlusion for AAV. Using this method, we examined the in vivo function of phospholamban (PLB) by stably transfecting PLB-null mice with AAV encoding PLB (AAV(PLB)). AAV(PLB) restored PLB protein to near control levels that colocalized with SERCA2A in cardiomyocytes. At baseline, PLB-null hearts exhibited enhanced systolic and diastolic function, but frequency-dependent reserve was blunted versus wild-type controls. These properties, particularly the frequency response, returned toward control 3 months after AAV(PLB) transfection.

CONCLUSIONS

The new simplified approach for murine whole-heart viral transfection should assist molecular physiology studies.

Characterization of in vitro and in vivo gene transfer properties of adenovirus serotype 35 vector

We have recently developed a replication-defective, recombinant adenovirus (Ad) vector composed of the whole Ad serotype 35 (Ad35), a member of subgroup B. We describe herein the in vitro and in vivo gene transfer properties of Ad35 vector in comparison with Ad serotype 5 (Ad5) and the Ad5F35 vector, which is a fiber-substituted Ad5 vector containing Ad35 fiber proteins. In vitro, Ad35 vector efficiently transduced not only human CAR-positive cells but also CAR-negative cells. Following intravenous administration into mice, both Ad5 and Ad35 vectors were rapidly cleared from the bloodstream with a half-life of approximately 3 min. Ad5 vector-mediated transgene expression predominantly occurred in liver parenchymal cells, although the Ad5 vector was delivered to both liver parenchymal and nonparenchymal cells. In contrast, Ad35 vector was efficiently taken up by liver nonparenchymal cells and mediated transduction efficiency in the liver on a level 4 log orders lower than the Ad5 vector. These findings demonstrate that Ad35 vector is an attractive vehicle for gene transfer into human cells, while the biodistribution profile of Ad35 vector in mice is much different from that of the Ad5 vector.

Tight positive regulation of transgene expression by a single adenovirus vector containing the rtTA and tTS expression cassettes in separate genome regions

We previously developed single adenovirus (Ad) vectors that contained the components for a tetracycline-regulatable gene-expression system in the E1 and E3 deletion regions, and showed that the Ad vectors containing the tet-on system exhibit a much inferior regulation of transgene expression than those containing the tet-off system. In many cases, the tet-on system may be preferable because of its positive regulation of transgene expression. To this end, in the present study, by introducing the latest generation reverse tetracycline-responsive transcriptional activator (rtTA2s-M2 or rtTA2s-S2) and the tetracycline-controlled transcriptional silencer (tTS) into the original tet-on system, we constructed various modified Ad-mediated tet-on systems. Among them, the novel single Ad vector, which contained three heterologous gene-expression cassettes of the gene of interest, rtTA2s-S2, and tTS in the E1 deletion region, the E3 deletion region, and the region between E4 and 3'ITR, respectively, displayed vastly improved doxycycline-inducible gene expression in terms of low basal expression, high induced expression, and high responsiveness to doxycycline both in vitro and in vivo. These results also suggest that the low responsiveness to doxycycline may explain why the original tet-on system in the context of the Ad vector is not effective in vivo. This is the first report describing the cloning of three heterologous gene-expression cassettes into three separate regions of the E1/E3-deleted Ad genome. This improved Ad-mediated tet-on system might be useful for gene therapy and greatly facilitate the analyses of gene function.

Generating MHC Class II+/Ii- phenotype after adenoviral delivery of both an expressible gene for MHC Class II inducer and an antisense Ii-RNA construct in tumor cells

Tumor cells engineered by gene transduction to be MHC Class II+/Ii- are novel APCs capable of presenting endogenous tumor antigen epitopes to activate T helper cells. The MHC Class II+/Ii- tumor cell phenotype is created by transfecting genes for either CIITA or IFN-gamma, and inhibiting induced Ii mRNA by an Ii reverse gene construct (Ii-RGC). Adenoviral vectors are preferred for the delivery of such genes because of high infection efficiency and ubiquity of the adenoviral receptor on many cell types and tumors. Here we show that at 5 MOI (multiplicity of infection), recombinant adenoviruses with CIITA or IFN-gamma genes converted virtually all MC-38 colon adenocarcinoma cells and Renca renal carcinoma cells in culture to MHC Class II+/Ii+ cells. A single recombinant adenovirus with both genes for IFN-gamma and Ii-RGC (rAV/IFN-gamma/Ii-RGC) efficiently induced the MHC Class II+/Ii- phenotype. Injection of tumor nodules with rAV/Ii-RGC and rAV/CIITA/IFN-gamma combined with a suboptimal dose of rAV/IL-2 induced a potent antitumor immune response. The methods are adaptable for producing enhanced genetic vaccines, attenuated virus vaccines (eg, vaccinia), and ex vivo cell-based vaccines (dendritic and tumor cells).

Viral vectors for dendritic cell-based immunotherapy

Dendritic cells (DCs) constitute a specialised system of antigen-presenting cells with a high capacity to induce and to modulate the immune response against microbial, tumour and self-antigens. New techniques to generate large amounts of DCs together with the molecular identification of human tumour-associated antigens (TAA) have opened new ways for antigen-specific cancer immunotherapies. DCs loaded either with TAA-derived MHC class I-specific synthetic peptides or with whole tumour cell preparations have been used in numerous clinical trials evaluating the efficacy of DCs in patients with cancer. However, the disadvantages of DCs pulsed with synthetic peptides from TAA include the uncertainty regarding the longevity of antigen presentation, the restriction by the patient's haplotype and the relatively low number of known MHC class I and in particular of MHC class II helper cell-related epitopes. Whole tumour cell preparations are difficult to standardise, and they depend on the availability of tumour cells. Thus the utilisation of viral vectors genetically modified to express TAA for the ex vivo transduction of DCs is an attractive alternative to achieve a MHC I- and MHC II-restricted presentation of tumoural antigens. To induce protective anti-tumoural immune response an increasing number of modified viral vectors have been used to transduce DCs. Although high transduction efficacies were reported for several viruses, analysis of the interaction of viral vectors with DCs has revealed several viral mechanisms that interfere with main functions of DCs, dampening somewhat the initial optimism in the field of DC transduction. However, promising results with different vectors have been achieved. In this review we summarise available data and discuss advantages and drawbacks of currently available vectors.

Adenovirus-mediated gene transfer to healing tendon--enhanced efficiency using a gelatin sponge

Adenovirus-mediated gene transfer is a potential method for enhancing tendon healing. We investigated the transfection of Ad5CMVntLacZ, an adenovirus containing the reporter gene LacZ, in primary cultured human rotator cuff tendon cells and in a rat Achilles tendon healing model in vivo. Ad5CMVempty, the adenoviral vector containing no inserted gene, was used as a control for adenoviral transfection alone. Activity of beta-galactosidase,the protein expressed by LacZ gene, was measured using a beta-galactosidase assay and detected visually by X-gal staining. Cultured cells were successfully transfected without impairing cell viability. Maximal beta-galactosidase activity was detected when cells were transfected at the dose of 1000 PFU/cell. The duration of LacZ expression was six days with a peak value at 24 h post-transfection. A transfection rate of 100% was obtained at 5000 PFU/cell. Successful in vivo transfection by Ad5CMVntLacZ was obtained in healing rat Achilles tendon as confirmed by X-gal staining. 0.4% of tendon cells were transfected when Ad5CMVntLacZ was injected into the tendon at a dose of 10(6) PFU. The rate rose to 2% with 10(8) PFU and 3% with 10(9) PFU. The duration of LacZ expression in vivo was 17 days. Transfection efficiency was enhanced threefold and localization improved when a gelatin sponge was used to deliver the adenovirus. The results demonstrate that adenovirus can be used to deliver a gene of interest to cultured human rotator cuff tendon cells and healing tendon, with gelatin sponge implantation enhancing adenoviral transfection efficiency in vivo.

Woodchuck hepatitis virus post-transcriptional regulation element enhances transgene expression from adenovirus vectors

In studies of both gene therapy and gene function, transgene expression can be modulated at both the transcriptional and post-transcriptional levels. In a previous study, we optimized the transcriptional regulatory elements for adenovirus (Ad) vectors to mediate efficient transgene expression, including promoter, enhancer, intron, and poly(A) sequence. In the present study, we systematically investigated the ability of the Woodchuck hepatitis virus post-transcriptional regulation element (WPRE) to enhance the expression of the luciferase gene, as a model gene, in the context of Ad vectors. We found that the WPRE in the sense orientation cloned between the luciferase gene and the poly(A) sequence stimulated 2- to 7-fold more luciferase expression in vitro and 2- to 50-fold more in the liver, kidney and lung of mouse than occurred without the use of the WPRE. The most efficient Ad vector in this study, which contained the improved CMV promoter (the conventional CMV promoter with the intron A) and the WPRE, showed more than 700-fold luciferase expression in mouse liver than did the Ad vector containing the conventional CMV promoter but no WPRE. These results indicate that inclusion of the WPRE, combined with the optimization of transcriptional regulatory elements in Ad vectors, will permit a given therapeutic goal to be achieved with substantially fewer viral particles. This information would be helpful for the construction of adenovirus vectors for studies regarding both gene therapy and gene function.

Regulated gene expression from adenovirus vectors: a systematic comparison of various inducible systems

Positively and tightly regulated gene expression is essential for gene function and gene therapy research. The currently-used inducible gene expression systems include tetracycline (Tet-on and T-REx), ecdysone, antiprogestin and dimerizer-based systems. Adenovirus (Ad) vectors play an important role in gene function and gene therapy research for their various advantages over other vector systems. Previously, we reported the inferiority of the Tet-on system as an inducible gene expression system in the context of Ad vectors in comparison with the Tet-off system. In this study, to identify an optimal system for regulated gene expression from Ad vectors, we made a rigorous direct comparison of these five inducible gene expression systems in three cell lines using the luciferase reporter gene. The highest sensitivity to the respective inducer was that of the dimerizer system, followed by the antiprogestin system. The lowest basal expression and the highest induction factor were both characteristic of the dimerizer system. Furthermore, the dimerizer and T-REx systems exhibited much higher induced expression levels than the other three systems. The elucidation of the characteristic features of each system should provide important information for widespread and feasible application of these systems. Overall, these results suggest the most appropriate inducible gene expression system in the context of Ad vectors to be the dimerizer system.

Generation of fiber-modified adenovirus vectors containing heterologous peptides in both the HI loop and C terminus of the fiber knob

BACKGROUND

Fiber-modified adenovirus (Ad) vectors can be effective in overcoming the limitations of conventional Ad vectors, specifically their inefficient gene transfer into cells lacking the primary receptor, the coxsackievirus and adenovirus receptor (CAR). Several types of fiber-modified Ad vectors have been developed. In this study, we evaluated the functionality of several fiber-modified Ad vectors.

METHODS

We developed a simple method based on in vitro ligation to construct Ad vectors containing heterologous foreign peptides in both the HI loop and C terminus of the fiber knob. A functional comparison of Ad vectors containing RGD and/or K7 (KKKKKKK) peptide in the HI loop or C terminus of the fiber knob was performed in several types of human, mouse, and rat cells, including CAR-positive and -negative cells, and tumor cells in mice in vivo.

RESULTS

In the case of the in vitro experiment, Ad vectors containing RGD peptide in the HI loop of the fiber knob showed a higher level of gene transfer than vectors containing RGD peptide at the C terminus of the fiber knob. Ad vectors containing K7 peptide at the C terminus of the fiber knob showed levels of gene transfer similar to those of Ad vectors containing RGD peptide in the HI loop of the fiber knob, depending on the cell type. Ad vectors containing both peptides in the HI loop or C terminus of the fiber knob showed the highest levels of gene transfer and a broader tropism. For gene transfer into tumor cells in vivo, the Ad vectors containing RGD peptide were the most efficient.

CONCLUSIONS

In the experiment using cultured cells, Ad vectors containing both RGD and K7 peptides were the most efficient with a broader tropism. In contrast, in the experiment in vivo, Ad vectors containing RGD peptide in the HI loop of the fiber knob were more efficient than the vectors containing K7 peptide (including double-modified vectors containing both the RGD and K7 peptides). These comparative analyses could provide a systemic reference for the use of fiber-modified Ad vectors. Our simple method, in which the peptide of interest can be expressed in Ad vectors in either the HI loop or the C terminus of the fiber knob, or both, could be a powerful tool for gene transfer into mammalian cells in studies of gene function as well as in gene therapy.

Current status of gene therapy for inherited lung diseases

Gene therapy as a treatment modality for pulmonary disorders has attracted significant interest over the past decade. Since the initiation of the first clinical trials for cystic fibrosis lung disease using recombinant adenovirus in the early 1990s, the field has encountered numerous obstacles including vector inflammation, inefficient delivery, and vector production. Despite these obstacles, enthusiasm for lung gene therapy remains high. In part, this enthusiasm is fueled through the diligence of numerous researchers whose studies continue to reveal great potential of new gene transfer vectors that demonstrate increased tropism for airway epithelia. Several newly identified serotypes of adeno-associated virus have demonstrated substantial promise in animal models and will likely surface soon in clinical trials. Furthermore, an increased understanding of vector biology has also led to the development of new technologies to enhance the efficiency and selectivity of gene delivery to the lung. Although the promise of gene therapy to the lung has yet to be realized, the recent concentrated efforts in the field that focus on the basic virology of vector development will undoubtedly reap great rewards over the next decade in treating lung diseases.

Gene therapy for restenosis: current status

Atherosclerosis is a major cause of morbidity and mortality in Western world. Vascular occlusion caused by atherosclerosis usually requires invasive treatment, such as surgical bypass or angioplasty. However, bypass graft failure and restenosis limit the usefulness of these procedures, with 20% of patients needing a new revascularisation procedure within 6 months of angioplasty. Numerous pharmacological agents have been investigated for the prevention of restenosis but none has shown undisputed efficacy in clinical medicine. Gene transfer offers a novel approach to the treatment of restenosis because of easy accessibility of vessels and already existing gene delivery methods. It can be used to overexpress therapeutically important proteins locally without high systemic toxicity, and the therapeutic effect can be targeted to a particular pathophysiological event. Promising results have been obtained from many pre-clinical experiments using therapeutic genes or oligonucleotides to prevent restenosis. Early clinical trials have shown that plasmid- and adenovirus-mediated vascular gene transfers can be conducted safely and are well tolerated. Ex vivo gene therapy with E2F-decoy succeeded in reducing graft occlusion rate after surgical bypass in a randomised, double-blind clinical trial. In the future, further development of gene delivery methods and vectors is needed to improve the efficacy and safety of gene therapy. Also, better knowledge of vascular biology at the molecular level is needed to find optimal strategies and gene combinations to treat restenosis. Provided that these difficulties can be solved, gene therapy offers an enormous potential for clinical medicine in the future.

DNA-based immunotherapy: potential for treatment of chronic viral hepatitis?

Persistent HBV and HCV infection represent major causes of chronic liver disease with a high risk of progression to liver cirrhosis and hepatocellular carcinoma (HCC). Conventional protein-based vaccines are highly efficacious in preventing HBV infection; whereas in therapeutic settings with chronically infected patients, results have been disappointing. Prophylactic vaccination against HCV infection has not yet been achieved due to many impediments including frequent spontaneous mutations of the virus with escape from immune system control. Using animal models it has been demonstrated that DNA-based immunisation strategies may overcome this problem because of their potential to induce immunity against multiple viral epitopes. DNA-based vaccines mimic the effect of live attenuated viral vaccines, eliciting cell mediated immunity in addition to inducing humoral responses. Efficacy may further be improved by addition of DNA encoding immunomodulatory cytokines and more recently, direct genetic modulation of antigen-presenting cells, such as dendritic cells (DC), has been shown to increase antigen-specific immune responses. This review focuses on immunological aspects of chronic HBV and HCV infection and on the potential of DNA- and DC-based vaccines for the treatment of chronic viral hepatitis.

In vivo expression of adenovirus-mediated lacZ gene in murine nasal mucosa

Adenovirus is a good tool for transferring exogenous genes into various organs because the virus has a wide spectrum of infection. In this report, we demonstrate that a recombinant adenovirus, Ax1CAlacZ, can transfer an exogenous lacZ gene into murine nasal mucosa in vivo. The efficiency of the exogenous gene expression varied for different cell types and was improved by optimizing the method of administration. In the olfactory region, the olfactory epithelia, sustentacular cells and olfactory nerve efficiently expressed lacZ gene transferred by Ax1CAlacZ using either of two administration methods, dripping or injecting. In contrast, in the respiratory region, the respiratory epithelia but not the subepithelial tissues expressed lacZ gene transferred by Ax1CAlacZ, and the efficiency of the gene transfer, which was low when the virus was administered by nasal drops, was improved when the virus was administered by injection. Our study demonstrated that gene transfer mediated by adenovirus is more efficient in the olfactory epithelia than in the respiratory epithelia, and may be applicable to nasal or paranasal diseases such as olfactory epithelial disturbances.

Adenovirus-based libraries: efficient generation of recombinant adenoviruses by positive selection with the adenovirus protease

Adenoviruses (Ad) deleted in the protease (PS) gene are capable of only one round of replication in non-complementing cells. This feature was exploited to develop a positive selection method for constructing adenoviral recombinants using ectopic expression of the PS gene in the E1 region. Very low levels of PS were sufficient to ensure the rescue of a PS-deleted Ad genome (Ad(Delta)PS), thereby eliminating deleterious effects PS over-expression might exert on cell or virus growth. In addition to the standard co-transfection method, an alternative protocol was developed in which the Ad5-(Delta)PS viral DNA was delivered by infection before subsequent transfection of 293 cells with the transfer vector. Under optimal conditions, at least one recombinant Ad per 10(3) cells was generated with 100% of the plaques being recombinant. Since the infection/transfection protocol is readily scalable, this represents the first method that allows for the easy construction of adenovirus vector (AdV) libraries with high diversities. This approach addresses in a novel way the bottleneck encountered when converting plasmid libraries, constructed in E. coli using a variety of well-established strategies, into corresponding AdV libraries. It maintains high diversity while generating recombinant viruses with 100% efficiency.

Transgene expression in neonatal mouse inner ear explants mediated by first and advanced generation adenovirus vectors

The mouse serves as a valuable model for treatment leading to the prevention and therapy of inner ear disease. Transgenic correction of genetic inner ear disease in mice may help develop treatment for human genetic inner ear disease. In mutations involving hair cells (HCs) or supporting cells (SCs), it is necessary to insert the wild-type transgenes directly into these cells. We used inner ear explants to characterize the transgenic expression using adenovirus-mediated reporter genes (bacterial lacZ). The variable parameters were the age of the explants (P1-P5), the type of vector (first and advanced generation adenovirus) and the genotype of the mouse (wild-type versus shaker-2 mutant). Transduction of cochlear HCs was detected at P1 and in some of the P3 cochleae. Low efficiency transduction of SCs was observed in P1 explants, but the efficiency increased with age and reached high levels at P5. The pattern of transduction was similar regardless of the genotype and the type of vector used. The data demonstrate that differentiating HCs and SCs in mouse explants can be transduced by adenovirus vectors, suggesting that cultures of mouse ears are a valuable model for developing inner ear gene therapy protocols.

CAR- or alphav integrin-binding ablated adenovirus vectors, but not fiber-modified vectors containing RGD peptide, do not change the systemic gene transfer properties in mice

Targeted gene delivery to the tissue of interest by recombinant adenovirus (Ad) vectors is limited by the relatively broad expression of the primary receptor, the coxsackievirus and adenovirus receptor (CAR), and the secondary receptor, alphav integrin. This problem could be overcome by mutating the fiber and penton base, which bind with CAR and alphav integrin, respectively. In this study, we constructed CAR-binding ablated Ad vectors and alphav integrin-binding ablated Ad vectors by mutation in the FG loop of fiber knob and in the RGD motif of penton base, respectively, and compared the gene transfer properties of their vectors into various types of cultured cells and mice with conventional Ad vectors. We also generated Ad vectors containing RGD peptide in the HI loop of the fiber knob. CAR-binding ablated Ad vectors mediated about 1% of gene transfer activity into CAR-positive cultured cells, compared with conventional Ad vectors, while alphav integrin-binding ablated Ad vectors maintained at least 76% of gene transfer activity into cultured CAR-positive cells. Inclusion of the RGD peptide into the HI loop of the fiber knob of CAR-binding ablated Ad vectors restored gene transfer activity in vitro. On the other hand, systemically administered CAR-binding ablated Ad vectors, as well as alphav integrin-binding ablated Ad vectors mediated similar levels of gene transfer into mouse liver with the conventional Ad vectors. These results suggest that continued interaction of either the fiber with CAR or the penton base with alphav integrin offers an effective route of virus entry into mouse liver in vivo. Inhibition of the interaction of both the fiber with CAR and the penton base with alphav integrin is likely to be crucial to the development of targeted Ad vectors.

Strength evaluation of transcriptional regulatory elements for transgene expression by adenovirus vector

In studies of both gene function and gene therapy, transgene expression may be assisted considerably through the use of transcriptional regulatory elements with high activity. In this study, we evaluated the strength of various transcriptional regulatory elements both in vitro (six types of cell line) and in vivo (mouse heart, lung, kidney, spleen, and liver) by adenovirus-mediated gene transfer. In the case of the promoter/enhancer (P/E), the activity of CMV P/E (from the human cytomegalovirus immediate-early 1 gene) and hybrid CA P/E (composed of the CMV enhancer and chicken beta-actin promoter) were investigated, both of which are known to be strong and widely used. While hybrid CA P/E showed a higher transgene expression activity than CMV P/E, the addition of the intron A sequence (the largest intron of CMV) to CMV P/E increased the activity of CMV P/E to the same or higher level than that of hybrid CA P/E. Concerning the polyadenylation signal (P(A)) sequence, one from the bovine growth hormone (BGH) gene was about two times more efficient than that from the Simian virus 40 (SV40) late gene, both in vitro and in vivo. In the context of the CMV P/E containing the intron A sequence, a further increase in transgene expression was obtained by the addition of a SV40 enhancer downstream from the P(A) sequence. The combination of the SV40 P(A) and a SV40 enhancer showed almost comparable activity to BGH P(A). This information would be helpful for the construction of adenovirus vectors for studies regarding both gene function and gene therapy.

The tet-off system is more effective than the tet-on system for regulating transgene expression in a single adenovirus vector

BACKGROUND

Control of transgene expression in mammalian cells is desirable for gene therapy and the study of gene function in basic research. This study evaluates the functionality of single adenovirus (Ad) vectors containing a tetracycline-controllable expression system (tet-off or tet-on system).

METHODS

An Ad-mediated binary transgene expression system was generated containing a tet-off or a tet-on system, which introduced the gene of interest with a tetracycline-regulatable promoter and the tetracycline-responsive transcriptional activator gene into the E1 and E3 deletion regions, respectively. The functionality of the Ad-mediated tet-off and tet-on systems was compared under various conditions in vitro and in vivo.

RESULTS

The Ad vector containing the tet-off system provided negative control of gene expression ranging from 20- to 500-fold, depending on the cell type and condition. In contrast, the Ad vector containing the tet-on system increased gene expression by only 2- to 28-fold and required about two-log orders higher concentration of an inducer (doxycycline) to switch on the gene expression, compared with the Ad vector containing the tet-off system.

CONCLUSION

Ad vectors containing the tet-off system are a better choice for regulated gene expression than Ad vectors containing the tet-on system. Single Ad vectors containing the tetracycline-controllable expression system will greatly facilitate in vitro and in vivo analyses of gene function and may be useful for gene therapy.

Enhanced antitumor effect and reduced vector dissemination with fiber-modified adenovirus vectors expressing herpes simplex virus thymidine kinase

There are at least two hurdles confronting the use of the adenovirus (Ad)-mediated herpes simplex virus thymidine kinase (HSVtk)/ganciclovir (GCV) system for the treatment of cancer. One is inefficient Ad vector-mediated gene transfer into tumor cells lacking the primary receptor, i.e., the coxsackievirus and adenovirus receptor (CAR). The other is hepatotoxicity due to unwanted vector spread into the liver, even when Ad vectors are injected intratumorally. Herein, we present an attractive strategy for overcoming such limitations based on use of a fiber-modified Ad vector containing an RGD peptide motif in the fiber knob. HSVtk-expressing Ad vectors containing mutant fiber (AdRGD-tk) or wild-type fiber (Ad-tk) were injected intratumorally into CAR-negative B16 melanoma cells inoculated into mice, after which GCV was injected intraperitoneally for 10 days. AdRGD-tk showed approximately 25 times more antitumor activity than Ad-tk. Histopathological studies suggested that liver damage in mice injected with AdRGD-tk was significantly lower than that in mice injected with Ad-tk. Intratumoral administration of luciferase-expressing Ad vectors containing the mutant fiber (AdRGD-L2) resulted in nearly 40 times more luciferase production in the tumor, but 8 times less production in the liver than the conventional Ad vectors (Ad-L2). These results indicate that combination of fiber-modified vectors and a HSVtk/GCV system is a potentially useful and safe approach for the treatment of tumors lacking CAR expression, and that fiber-modified vectors could be of great utility for gene therapy and gene transfer experiments.

Adenovirus vectors containing chimeric type 5 and type 35 fiber proteins exhibit altered and expanded tropism and increase the size limit of foreign genes

Adenovirus (Ad) fiber proteins are responsible for the initial attachment of the virion to the cell membrane. Most Ad vectors currently in use are based on the Ad type 5 (Ad5), which belong to subgroup C, and use the coxsackievirus and adenovirus receptors (CAR) as the initial receptor. Ad35, which belongs to subgroup B, recognizes unknown receptor(s) other than CAR. In this study, the feasibility of the Ad vector containing Ad5/35 chimeric fiber protein was examined in a wide variety of cell types, such as CAR-positive or -negative human tumor cells, rodent cells, and blood cells (a total of 20 cell types), and in mice in vivo. Transduction data suggested that the Ad vectors containing the Ad5/35 chimeric fiber protein exhibited altered and expanded tropism when compared with the Ad5-based vector. The chimeric vector also allows the packaging of larger foreign DNAs than the conventional Ad5-based vector, which can package approximately 8.1-8.2 kb of foreign DNA. The chimeric vector containing approximately 8.8 kb of foreign DNA was generated without affecting the viral growth rate and titer. These results suggested that inclusion of the Ad35 fiber protein into the Ad5-based vector could lead to an improved efficiency in gene therapy and in gene transfer experiments, especially for the cells lacking in sufficient CAR expression.

High-efficiency adenovirus-mediated in vivo gene transfer into neonatal and adult rodent skeletal muscle

Several methodological limitations have emerged in the use of viral gene transfer into skeletal muscle. First, because the nuclei of mature muscle fibers do not undergo division, the use of strategies involving replicative integration of exogenous DNA is greatly limited. Another important limitation concerns the maturation-dependent loss in muscle fiber infectivity with adenoviral vectors. In this study, we investigated the possibility that high-titer infections with recombinant adenovirus, expressing a foreign marker gene under the control of a strong viral promoter, can significantly improve the efficiency of gene transfer in vivo into neonatal and adult rat skeletal muscle. High-titer (2 x 10(10) plaque forming units) intramuscular injection of replication-defective adenovirus vector, expressing green fluorescent protein (GFP) under the control of cytomegalovirus promoter, resulted in GFP expression in 99 +/- 0.34% of fibers in the adult soleus muscle and in approximately 85 +/- 1.44% of fibers in the adult tibialis anterior muscle. Interestingly, reduction in injected adenoviral dose significantly reduced the number of GFP-positive fibers in the adult tibialis anterior muscle, but not in the soleus muscle. However, in neonates, adenoviral infection resulted in GFP expression in 96-99% of the fibers in the tibialis anterior and the gastrocnemius muscles regardless of administered adenoviral dose.

Feline hyperthyroidism: advances towards novel molecular therapeutics

Feline hyperthyroidism is the most common endocrine disorder of the elderly cat. Traditionally, the disease is treated by surgical thyroidectomy, medical management with antithyroid drugs or radiation therapy using iodine-131. However, none of these treatments is ideal and molecular therapeutics may offer novel methods of treating the disease. This article reviews the background of, and preliminary investigations into, the development of a transcriptionally targeted somatic gene therapy strategy for the treatment of this feline condition.

Genetic targeting of the renin-angiotensin system for long-term control of hypertension

Although traditional approaches are effective for the treatment and control of hypertension, they have not succeeded in curing the disease, and have therefore reached a plateau. As a result of the completion of the Human Genome Project and the continuous advancement in gene delivery systems, it is now possible to investigate genetic means for the treatment and possible cure for hypertension. In this review we discuss the potential of genetic targeting of the renin-angiotensin system for the treatment of hypertension. We provide examples of various approaches that have used antisense technology with a high degree of success. We focus on our own research, which targets the use of antisense of the angiotensin type I receptor in various models of hypertension. Finally, we discuss the future of antisense technology in the treatment of human hypertension.

Restoration of deficient membrane proteins in the cardiomyopathic hamster by in vivo cardiac gene transfer

BACKGROUND

One of the most important problems in developing in vivo cardiac gene transfer has been low transfection efficiency. A novel in vivo technique was developed, tested in normal hamsters, and the feasibility of restoring a deficient structural protein (delta-sarcoglycan) in the cardiomyopathic (CM) hamster evaluated.

METHODS AND RESULTS

Adenoviral (AdV) vectors encoding either the lacZ gene or delta-sarcoglycan gene were constructed. Hypothermia was achieved in hamsters by external body cooling to a rectal temperature of 18 to 25 degrees C. Through a small thoracotomy, the ascending aorta and the main pulmonary artery were occluded with snares, and cardioplegic solution containing histamine was injected into the aortic root; viral constructs were delivered 3 to 5 minutes later followed by release of the occluders and rewarming. Four days later, homogeneous beta-galactosidase expression was detected throughout the ventricles of the normal hearts (average 77.3+/-9.0% [SEM] of left ventricular myocytes). At 1 and 3 weeks after transfection, immunostaining showed extensive restoration of delta-sarcoglycan as well as alpha- and beta-sarcoglycan proteins to the myocyte membranes, despite loss of beta-galactosidase expression at 3 weeks. Also, at 3 weeks after gene transfer, there was significantly less progression of left ventricular dysfunction assessed as percent change in fractional shortening compared with controls.

CONCLUSIONS

This study demonstrates the feasibility of high efficiency in vivo myocardial gene transfer and shows application in improving the level of a deficient cardiac structural protein and cardiac function in CM hamsters. The approach should be useful for assessing effects of expressing other genes that influence the structure or function of the normal and failing heart.

Immunization with type 5 adenovirus recombinant for a tumor antigen in combination with recombinant canarypox virus (ALVAC) cytokine gene delivery induces destruction of established prostate tumors

Prostate-specific antigen (PSA) is expressed by prostate epithelial cells and has a highly restricted tissue distribution. Prostatic malignancies in 95% of patients continue to express PSA, making this antigen a good candidate for targeted immunotherapy. The goals of our studies are to generate a recombinant PSA adenovirus type 5 (Ad5-PSA) that is safe and effectively activates a PSA-specific T-cell response capable of eliminating prostate cancer cells, and to characterize the immunologic basis for this rejection. Here we show that immunization of mice with Ad5-PSA induced PSA-specific cellular and humoral immunity that was protective against a subcutaneous challenge with RM11 prostate cancer cells expressing PSA (RM11psa), but not mock-transfected RM11 tumor cells (RM11neo). Mice immunized with recombinant adenovirus type 5 encoding beta-galactosidase (Ad5-lacZ) did not generate protective immunity. Antitumor activity was predominantly mediated by CD8(+) T lymphocytes. Although Ad5-PSA immunization prior to RM11psa challenge was protective, Ad5-PSA immunization alone was not able to control the growth of existing RM11psa tumors. In contrast, established RM11psa tumors ranging in size from 500 to 1,000 mm(3) were efficiently eliminated if Ad5-PSA priming was followed 7 days later by intratumoral injection of recombinant canarypox viruses (ALVAC) encoding interleukin-12 (IL-12), IL-2, and tumor necrosis factor-alpha. In this case, antitumor immunity was still dominated by CD8(+) T lymphocytes, but natural killer cells became necessary for a maximal response. These data provide information on the effector cell populations in a protective immune response to prostate cancer and demonstrate the utility of an Ad5-PSA vaccine combined with cytokine gene delivery to eliminate large established tumors that are refractory to other interventional methods.

Efficient gene transfer by fiber-mutant adenoviral vectors containing RGD peptide

One of the hurdles to adenovirus (Ad)-mediated gene transfer is that Ad vectors mediate inefficient gene transfer into cells lacking in the primary receptors, Coxsackievirus and adenovirus receptor (CAR). We previously developed a fiber-mutant Ad vector containing the Arg-Gly-Asp (RGD)-containing peptide motif on the HI loop of the fiber knob, and showed that the mutant vector had enhanced gene transfer activity to human glioma cells, which showed little CAR expression, compared to the vector containing wild type fiber. In this study, the feasibility of the Ad vector containing RGD peptide on the fiber knob was examined in a wide variety of cell types: CAR-positive or -negative human tumor cells, mouse cells, and leukemia cells. The mutant vector infected the cells, which lacked CAR expression but showed alpha(v) integrin expression, about 10-1000 times more efficiently than the vector containing wild type fiber via an RGD-integrin (alpha(v)beta3 and alpha(v)beta5)-dependent, CAR-independent cell entry pathway. The results of this study indicate that Ad vector containing RGD peptide on the fiber knob could be of great utility for gene therapy and gene transfer experiments.

Characteristics of adenovirus-mediated tetracycline-controllable expression system

The combination of recombinant adenovirus (Ad) vectors and the tetracycline-controllable expression system is clearly an advantage in gene therapy and gene transfer experiment. In this study, we examined the characteristics of Ad vectors containing the tet-off or tet-on system. The Ad vector containing the tet-off system showed tightly regulatable transgene expression even at low MOI (multiplicity of infection). In contrast, regulation of gene expression by the Ad vector containing the tet-on system was not tight at low MOI, while it showed moderate regulation at high MOI (MOI=100). The Ad vector-mediated tet-on system showed lower inducible and higher background (basal) luciferase production than that of the Ad vector-mediated tet-off system. Moreover, the former system required a concentration of doxycycline, a derivative of tetracycline, approx. 2-3 log orders higher than that of the latter system to switch the luciferase expression. A combination of the vector containing the tet-on system and the vector containing the tetracycline-controlled transcriptional silencer (tTS) gene reduced the background luciferase production and improved regulation. These results suggest that the Ad vector containing the tet-off system is considered to be functionally superior to the vector containing the tet-on system. Care should be taken regarding regulation (especially lower inducibility and higher background), which is decreased in the Ad vector-mediated tet-on system in comparison with the tet-off system. The Ad vector containing the tetracycline-controllable expression system should offer a powerful tool for gene therapy and gene transfer experimentation.

Ectopic expression of the coxsackievirus and adenovirus receptor increases susceptibility to adenoviral infection in the human cervical cancer cell line, SiHa

The expression level of the coxsackievirus and adenovirus receptor (CAR) gene in human cervical cancer cell lines (Hela, Caski, HT-3, and SiHa) appears to be correlated with their susceptibility to adenoviral vector-based gene transfer. Hela, Caski, and HT-3 cells, which express the CAR molecule on the cell surface, showed a higher susceptibility to infection of AdCMVGFP than SiHa cells with no detectable level of CAR expression. Transient expression of the CAR gene in SiHa cells dramatically enhanced the susceptibility to adenoviral infection. Furthermore, SiHa-CAR, a stable transfectant which expresses the CAR gene showed a highly increased susceptibility to adenoviral infection in contrast to SiHa. These results demonstrate that the low susceptibility of SiHa to adenoviral infection is closely related to its loss of the CAR gene expression. In addition, the low infection efficacy can be overcome by the ectopic expression of the CAR gene. These results also give insight into a possible application of the CAR gene to adenovirus-mediated gene delivery.

Adenovirus gene transfer vectors inhibit growth of lymphatic tumor metastases independent of a therapeutic transgene

Adenovirus (Ad) gene transfer vectors traffic to regional lymph nodes (RLNs) after footpad injections in mice, resulting in localized production of interferon gamma (IFN-gamma). With this background, we evaluated the hypothesis that Ad vector administration may inhibit RLN tumor metastasis independent of the transgene in the expression cassette. Tumors of MM48, a cell line with a propensity toward lymphogenous metastasis, were established in the footpads of syngeneic C3H mice, and E1(-)E3(-) Ad vectors encoding no transgene (AdNull) or encoding an irrelevant transgene (AdCD; Escherichia coli cytosine deaminase with no 5-fluorocytosine administration) were administered (10(10) particles) in a peritumoral location. Both vectors suppressed the growth of tumor in the regional (popliteal) lymph node. This effect was localized to the regional, but not distant, lymph nodes (p < 0.05). Heat inactivation of the vector or decreasing the dose of the vector to 10(9) particles did not suppress RLN growth of the tumor when compared with 10(10) particles of active AdNull (p < 0.05 and p < 0.01, respectively). The ability of an E1(-)E4(-) vector expressing beta-galactosidase (AdRSVbetagal.11) to suppress RLN tumor growth showed that the E4 region of the Ad vector was not responsible for the effect. Blocking either IFN-gamma or natural killer (NK) cells with systemic antibody treatment in immunocompetent mice allowed rapid growth of RLN metastases despite Ad vector administration, and Ad vector injection into the footpads of tumor-free mice induced the accumulation of NK cells in the RLN. These data demonstrate that, in a metastatic murine tumor model, a low dose (10(10) particles) of replication-deficient Ad vectors inhibits RLN metastases independent of a therapeutic transgene, an effect that is mediated, at least in part, by IFN-gamma and NK cells.

Cationic polymer and lipids augment adenovirus-mediated gene transfer to cerebral arteries in vivo

Adenovirus-mediated gene transfer to blood vessels is relatively inefficient because binding of adenovirus to vessels is limited. The authors have reported that incorporation of cationic polymer and lipids with adenovirus augments gene transfer to blood vessels ex vivo. In this study, the authors determined whether complexes of adenovirus and cations improve efficiency of gene transfer in vivo. Poly-L-lysine, lipofectamine, or lipofectin was complexed with adenovirus encoding beta-galactosidase. Optimum ratios of the cations per adenovirus were determined by gene transfer to fibroblasts. After injection of the adenovirus into the cisterna magna of anesthetized rabbits, transgene activity was greater in the adventitia of intracranial arteries and meninges after injection of the complexes than adenovirus alone. Thirty minutes after application of adenovirus with the cations, binding of adenovirus to fibroblast cells in vitro or the basilar artery in vivo (by Southern blot analysis) was augmented, which suggests that enhanced binding of virus contributes to augmentation of transgene expression. Thus, cationic polymer and lipids improve transgene expression in intracranial arteries, primarily in the adventitia, after adenovirus-mediated gene transfer in vivo. This strategy may be applicable to studies of gene transfer and eventually for gene therapy.

Molecular therapeutics of liver disease

Fundamental advances in biomedical research will revolutionize the prevention and treatment of liver disease during the early twenty-first century. Recent progress in gene-, cell-, and recombinant protein-based therapeutics will contribute to this revolution, although formidable obstacles currently prevent the clinical application of these novel therapies. Eventually, these obstacles will be overcome, and molecular therapeutics of liver disease will become a clinical reality. As a result, the new millennium will be a very interesting time to practice hepatology.